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//-
// Copyright 2017 Jason Lingle
//
// Licensed under the Apache License, Version 2.0 <LICENSE-APACHE or
// http://www.apache.org/licenses/LICENSE-2.0> or the MIT license
// <LICENSE-MIT or http://opensource.org/licenses/MIT>, at your
// option. This file may not be copied, modified, or distributed
// except according to those terms.
use crate::std_facade::{fmt, Arc};
use core::mem;
use crate::strategy::fuse::Fuse;
use crate::strategy::traits::*;
use crate::test_runner::*;
/// Adaptor that flattens a `Strategy` which produces other `Strategy`s into a
/// `Strategy` that picks one of those strategies and then picks values from
/// it.
#[derive(Debug, Clone, Copy)]
#[must_use = "strategies do nothing unless used"]
pub struct Flatten<S> {
source: S,
}
impl<S: Strategy> Flatten<S> {
/// Wrap `source` to flatten it.
pub fn new(source: S) -> Self {
Flatten { source }
}
}
impl<S: Strategy> Strategy for Flatten<S>
where
S::Value: Strategy,
{
type Tree = FlattenValueTree<S::Tree>;
type Value = <S::Value as Strategy>::Value;
fn new_tree(&self, runner: &mut TestRunner) -> NewTree<Self> {
let meta = self.source.new_tree(runner)?;
FlattenValueTree::new(runner, meta)
}
}
/// The `ValueTree` produced by `Flatten`.
pub struct FlattenValueTree<S: ValueTree>
where
S::Value: Strategy,
{
meta: Fuse<S>,
current: Fuse<<S::Value as Strategy>::Tree>,
// The final value to produce after successive calls to complicate() on the
// underlying objects return false.
final_complication: Option<Fuse<<S::Value as Strategy>::Tree>>,
// When `simplify()` or `complicate()` causes a new `Strategy` to be
// chosen, we need to find a new failing input for that case. To do this,
// we implement `complicate()` by regenerating values up to a number of
// times corresponding to the maximum number of test cases. A `simplify()`
// which does not cause a new strategy to be chosen always resets
// `complicate_regen_remaining` to 0.
//
// This does unfortunately depart from the direct interpretation of
// simplify/complicate as binary search, but is still easier to think about
// than other implementations of higher-order strategies.
runner: TestRunner,
complicate_regen_remaining: u32,
}
impl<S: ValueTree> Clone for FlattenValueTree<S>
where
S::Value: Strategy + Clone,
S: Clone,
<S::Value as Strategy>::Tree: Clone,
{
fn clone(&self) -> Self {
FlattenValueTree {
meta: self.meta.clone(),
current: self.current.clone(),
final_complication: self.final_complication.clone(),
runner: self.runner.clone(),
complicate_regen_remaining: self.complicate_regen_remaining,
}
}
}
impl<S: ValueTree> fmt::Debug for FlattenValueTree<S>
where
S::Value: Strategy,
S: fmt::Debug,
<S::Value as Strategy>::Tree: fmt::Debug,
{
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
f.debug_struct("FlattenValueTree")
.field("meta", &self.meta)
.field("current", &self.current)
.field("final_complication", &self.final_complication)
.field(
"complicate_regen_remaining",
&self.complicate_regen_remaining,
)
.finish()
}
}
impl<S: ValueTree> FlattenValueTree<S>
where
S::Value: Strategy,
{
fn new(runner: &mut TestRunner, meta: S) -> Result<Self, Reason> {
let current = meta.current().new_tree(runner)?;
Ok(FlattenValueTree {
meta: Fuse::new(meta),
current: Fuse::new(current),
final_complication: None,
runner: runner.partial_clone(),
complicate_regen_remaining: 0,
})
}
}
impl<S: ValueTree> ValueTree for FlattenValueTree<S>
where
S::Value: Strategy,
{
type Value = <S::Value as Strategy>::Value;
fn current(&self) -> Self::Value {
self.current.current()
}
fn simplify(&mut self) -> bool {
self.complicate_regen_remaining = 0;
if self.current.simplify() {
// Now that we've simplified the derivative value, we can't
// re-complicate the meta value unless it gets simplified again.
// We also mustn't complicate back to whatever's in
// `final_complication` since the new state of `self.current` is
// the most complicated state.
self.meta.disallow_complicate();
self.final_complication = None;
true
} else if !self.meta.simplify() {
false
} else if let Ok(v) = self.meta.current().new_tree(&mut self.runner) {
// Shift current into final_complication and `v` into
// `current`. We also need to prevent that value from
// complicating beyond the current point in the future
// since we're going to return `true` from `simplify()`
// ourselves.
self.current.disallow_complicate();
self.final_complication = Some(Fuse::new(v));
mem::swap(
self.final_complication.as_mut().unwrap(),
&mut self.current,
);
// Initially complicate by regenerating the chosen value.
self.complicate_regen_remaining = self.runner.config().cases;
true
} else {
false
}
}
fn complicate(&mut self) -> bool {
if self.complicate_regen_remaining > 0 {
if self.runner.flat_map_regen() {
self.complicate_regen_remaining -= 1;
if let Ok(v) = self.meta.current().new_tree(&mut self.runner) {
self.current = Fuse::new(v);
return true;
}
} else {
self.complicate_regen_remaining = 0;
}
}
if self.current.complicate() {
return true;
} else if self.meta.complicate() {
if let Ok(v) = self.meta.current().new_tree(&mut self.runner) {
self.complicate_regen_remaining = self.runner.config().cases;
self.current = Fuse::new(v);
return true;
}
}
if let Some(v) = self.final_complication.take() {
self.current = v;
true
} else {
false
}
}
}
/// Similar to `Flatten`, but does not shrink the input strategy.
///
/// See `Strategy::prop_ind_flat_map()` fore more details.
#[derive(Clone, Copy, Debug)]
pub struct IndFlatten<S>(pub(super) S);
impl<S: Strategy> Strategy for IndFlatten<S>
where
S::Value: Strategy,
{
type Tree = <S::Value as Strategy>::Tree;
type Value = <S::Value as Strategy>::Value;
fn new_tree(&self, runner: &mut TestRunner) -> NewTree<Self> {
let inner = self.0.new_tree(runner)?;
inner.current().new_tree(runner)
}
}
/// Similar to `Map` plus `Flatten`, but does not shrink the input strategy and
/// passes the original input through.
///
/// See `Strategy::prop_ind_flat_map2()` for more details.
pub struct IndFlattenMap<S, F> {
pub(super) source: S,
pub(super) fun: Arc<F>,
}
impl<S: fmt::Debug, F> fmt::Debug for IndFlattenMap<S, F> {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
f.debug_struct("IndFlattenMap")
.field("source", &self.source)
.field("fun", &"<function>")
.finish()
}
}
impl<S: Clone, F> Clone for IndFlattenMap<S, F> {
fn clone(&self) -> Self {
IndFlattenMap {
source: self.source.clone(),
fun: Arc::clone(&self.fun),
}
}
}
impl<S: Strategy, R: Strategy, F: Fn(S::Value) -> R> Strategy
for IndFlattenMap<S, F>
{
type Tree = crate::tuple::TupleValueTree<(S::Tree, R::Tree)>;
type Value = (S::Value, R::Value);
fn new_tree(&self, runner: &mut TestRunner) -> NewTree<Self> {
let left = self.source.new_tree(runner)?;
let right_source = (self.fun)(left.current());
let right = right_source.new_tree(runner)?;
Ok(crate::tuple::TupleValueTree::new((left, right)))
}
}
#[cfg(test)]
mod test {
use super::*;
use std::u32;
use crate::strategy::just::Just;
use crate::test_runner::Config;
#[test]
fn test_flat_map() {
// Pick random integer A, then random integer B which is ±5 of A and
// assert that B <= A if A > 10000. Shrinking should always converge to
// A=10001, B=10002.
let input = (0..65536).prop_flat_map(|a| (Just(a), (a - 5..a + 5)));
let mut failures = 0;
let mut runner = TestRunner::new_with_rng(
Config {
max_shrink_iters: u32::MAX - 1,
..Config::default()
},
TestRng::deterministic_rng(RngAlgorithm::default()),
);
for _ in 0..1000 {
let case = input.new_tree(&mut runner).unwrap();
let result = runner.run_one(case, |(a, b)| {
if a <= 10000 || b <= a {
Ok(())
} else {
Err(TestCaseError::fail("fail"))
}
});
match result {
Ok(_) => {}
Err(TestError::Fail(_, v)) => {
failures += 1;
assert_eq!((10001, 10002), v);
}
result => panic!("Unexpected result: {:?}", result),
}
}
assert!(failures > 250);
}
#[test]
fn test_flat_map_sanity() {
check_strategy_sanity(
(0..65536).prop_flat_map(|a| (Just(a), (a - 5..a + 5))),
None,
);
}
#[test]
fn flat_map_respects_regen_limit() {
use std::sync::atomic::{AtomicBool, Ordering};
let input = (0..65536)
.prop_flat_map(|_| 0..65536)
.prop_flat_map(|_| 0..65536)
.prop_flat_map(|_| 0..65536)
.prop_flat_map(|_| 0..65536)
.prop_flat_map(|_| 0..65536);
// Arteficially make the first case fail and all others pass, so that
// the regeneration logic futilely searches for another failing
// example and eventually gives up. Unfortunately, the test is sort of
// semi-decidable; if the limit *doesn't* work, the test just runs
// almost forever.
let pass = AtomicBool::new(false);
let mut runner = TestRunner::new(Config {
max_flat_map_regens: 1000,
..Config::default()
});
let case = input.new_tree(&mut runner).unwrap();
let _ = runner.run_one(case, |_| {
// Only the first run fails, all others succeed
prop_assert!(pass.fetch_or(true, Ordering::SeqCst));
Ok(())
});
}
#[test]
fn test_ind_flat_map_sanity() {
check_strategy_sanity(
(0..65536).prop_ind_flat_map(|a| (Just(a), (a - 5..a + 5))),
None,
);
}
#[test]
fn test_ind_flat_map2_sanity() {
check_strategy_sanity(
(0..65536).prop_ind_flat_map2(|a| a - 5..a + 5),
None,
);
}
}
|